KR200223322Y1 - 3d image display system - Google Patents

Abstract

The present invention provides a three-dimensional (3D) image display system.

The present invention includes a display device, an image polarization processing device, an image filter, an image synchronizer, and an electronic liquid crystal polarizing glasses. This structure effectively flickers when displaying a 3D image using a known continuous alternate scanning method when using a local visual space shutter processing method and scanning the image at a low frequency by appropriately adjusting the brightness of the image. (flickering phenomenon) can be reduced.

Description

3D image display system {3D IMAGE DISPLAY SYSTEM}

The present invention relates to a three-dimensional (3D) image display system that can improve the flickering phenomenon in the visual space generated when scanning at a low frequency in a known kind of liquid crystal shutter spectacle will be. In particular, any one type of display device, image polarization processing device, image filter, image synchronizer, electronic liquid crystal polarizing glasses, and 3D using a known low-frequency continuous-sequential display technique When viewing an image, first, the range of the possibility of occurrence of flickering by using a polarized optical method is limited to the screen of the display device, which is a small part of the visual space, and separately limited by the image filter using the image filter. The present invention relates to a 3D image display system capable of appropriately reducing flicker brightness and effectively reducing flicker even at low scanning frequencies such as 60 Hz.

The so-called "blinking phenomenon" occurs when viewing stereoscopic images using traditional televisions and 3D electronic liquid crystal shutter glasses. The main cause of this "blinking phenomenon" will be described next.

The electronic liquid crystal shutter on the 3D glasses performs optical processing of penetrating and shiedling over the entire visual space of the viewer, so that if the scanning frequency of the screen is not high enough, the ambient light source other than the display screen This is because intense flickering occurs due to the slow opening and closing of the electronic liquid crystal shutter.

1 is a schematic diagram showing the flickering phenomenon that occurs when the known 3D electronic liquid crystal shutter glasses operate at low frequencies. In general, when viewing a stereoscopic image using the 3D electronic liquid crystal shutter glasses 1, the left stereoscopic image L and the right stereoscopic image R are continuously replaced according to the " continuous replacement scanning " Inject in. In addition, at the same time, the left electronic liquid crystal shutter 2 and the right electronic liquid crystal shutter 3 are opened and closed while being synchronized so that stereoscopic images can be viewed.

However, since the electronic liquid crystal shutters uniformly pass and block the screen 9 of the display device and all the surrounding light sources 8, when the left stereoscopic image L is scanned and appears on the screen 9 of the display device. The left electronic liquid crystal shutter 2 is in an open state, and the right electronic liquid crystal shutter 3 is in an closed state. For this reason, the left eye 5 of the viewer who sees the image can see the left stereoscopic image L, the image 11 of the display device device, and the image 10 around the left side, while the right eye 6 can see any image ( 7) can not see.

On the contrary, when the right stereoscopic image R is scanned and appears on the screen 9 of the display device, the right electronic liquid crystal shutter 3 is in an open state, and the left electronic liquid crystal shutter 2 is in a closed state. Therefore, the right eye 6 of the viewer can see the right stereoscopic image R, the image 15 of the display device, and the right peripheral image 14, while the left eye 5 can see any image 7. ) Can't see.

As described above, the light source of the screen causes flicker at low image scanning frequencies in the left and right eyes of the viewer, and the ambient light sources other than the screen generate more intense flicker.

In order to solve the drawbacks of the known structure, the present invention aims to provide a 3D imaging system.

It can effectively solve the problem of the occurrence of flicker, and can be applied to a TV of a low scanning frequency can provide an environment for viewing a comfortable stereoscopic image.

1 is a schematic diagram showing the flickering phenomenon that occurs when the known 3D electronic liquid crystal shutter glasses operate at low frequencies.

Fig. 2 is a schematic diagram showing the optical principle of “local visual space shutter processing” of the present invention.

3 is a system block diagram of a 3D image display system of the present invention.

Figure 4 (A) is a view showing the optical action in the blocking state of the liquid crystal polarizer according to the present invention.

4 (B) is a view showing an optical action in the pass state of the liquid crystal polarizer according to the present invention.

In a 3D image display system including a display device, an image polarization processing device, an image filter, an image synchronizer, and an electronic liquid crystal polarizing glasses according to the present invention, the display device is used for outputting a synchronization signal of stereoscopic images and screen scanning, The synchronization signal output of the screen scanning may be a wired transmission method or a wireless transmission method, and the image polarization processing apparatus receives a stereoscopic image and polarizes the received stereoscopic image, and outputs the polarized image. The luminance of the received image is appropriately lowered and then output, the image synchronizer receives the synchronization signal of the screen scan, outputs a drive signal of a set of left and right liquid crystal polarizers, and the electronic liquid crystal polarizing glasses A pair of left and right liquid crystal polarizers are mounted on the screen, and an image and a drive signal of the left and right liquid crystal polarizers are received. The polarization action state of the left and right liquid crystal polarizers are individually set according to a signal, and the 3D image display system uses a localizing the shuttering process in the limited visual space, and opens and closes the shutter. The optical action of the display device is limited to the range of the screen of the display device, and the optical action of opening and closing the shutter is not generated for the ambient light sources other than the screen of the display device. Thus, the television, monitor, liquid crystal monitor, plasma display device, projector, etc. When displaying the 3D image using the display device, the flickering effect is effectively eliminated.

In addition, the liquid crystal polarizer of the electronic liquid crystal polarizing glasses according to the present invention is composed of two conductive transparent glasses, a liquid crystal molecular layer, and a linear polarizing plate, wherein the two conductive transparent glasses seal the liquid crystal molecular layer. And receive external electrical signals, and the liquid crystal molecular layer generates an optical action on an image having linearly polarized light according to an external electrical voltage signal, and when there is no external electrical voltage signal. The image is output by rotating the polarization direction of the image having the linear polarization by 90 degrees, and outputs the image without changing the polarization direction of the image having the linear polarization when there is an external electric voltage signal. The optical action of filtration, or passage, is generated for images with linearly polarized light.

The image polarization processing apparatus of the present invention is a linear polarizer.

Furthermore, the image filter and the image synchronization device of the present invention are installed in a frame of the electronic liquid crystal polarizing glasses.

In order to solve this problem, the present invention provides the following 3D image display system.

When displaying a stereoscopic image using a known display device such as a television, a monitor, a liquid crystal monitor, a plasma display device, a projector, or the like, the present invention does not change the inherent scanning frequency conditions of such a display device. It is possible to improve the flicker phenomenon caused by. The optical method of the "local visual space shutter process" of the present invention reduces the range of the entire visual space to the optical action of opening and closing the shutter, and limits the screen area of the display device to the shutter. It does not generate the optical action of opening and closing. Therefore, among the images sensed by the retina of the viewer, only three-dimensional images displayed on the screen of the display device cause flickering, and other ambient light sources do not, in principle, cause flickering. In addition, for the image causing this flickering phenomenon, the brightness can be lowered appropriately to reduce the flickering phenomenon generated because the scanning frequency is too low.

The present invention utilizes the optical principle of "local visual space shutter processing" and can reduce the flickering phenomenon through a display screen, an image polarization processing apparatus, an image filter, an image synchronizer, and an electronic liquid crystal polarizing glasses.

2 is a schematic diagram showing the optical principle of "local visual space shutter processing" of the present invention. In the following, in order to explain the optical principle conveniently and specifically, a linear vertically-polarized light is described as an example for the polarized polarization portion.

A light source that can be recognized in the visual space of the left and right eyes of the viewer of the image is divided into a screen 29 of the display device and an ambient light source 28 other than the screen 29. First, when polarized polarization processing is performed on the light source of the screen 29 of the display device, the left and right stereoscopic images L and R projected from the screen 29 are both vertically polarized light sources. In addition, although the polarizing glasses 21 which can control the polarization direction are used, the left and right polarizing devices 22 and 23 of the glasses 21 thereby set the polarization state to be synchronized with the scanning display time of the image. Thus, the opening and closing action of the shutter is realized only for the light source for the screen 29 of the display device. On the other hand, for the ambient light source 28 other than the screen 29, the opening / closing action of the shutter is not performed.

Further, when the left stereoscopic image L is scanned and appears on the screen 29 of the display device, the left stereoscopic image L becomes a vertically polarized light source through the processing of linear vertically polarized light, and at the same time, The polarization state becomes a vertical polarization state. Therefore, the left stereoscopic image L and the ambient light source 28 can be passed through. On the other hand, since the polarization state of the right polarizing device 23 is a horizontal polarization state, only the ambient light source 28 can pass, and the left stereoscopic image L is blocked. For this reason, the left eye 25 of the viewer can see the left stereoscopic image L and the left surrounding image 30, and the right eye 26 sees the right environmental image 31, while the left stereoscopic image L is Can't see

Further, when the right stereoscopic image R is scanned and appears on the screen 29 of the display device, through the linear vertical polarization process, the right stereoscopic image R becomes a vertically polarized light source, and at the same time, the right polarizer 23 The polarization state of becomes a vertical polarization state. Therefore, the right stereoscopic image R and the ambient light source 28 can be passed through. On the other hand, since the polarization state of the left polarizing device 22 is a horizontal polarization state, only the ambient light source 28 is passed and the right stereoscopic image R is blocked. Therefore, the right eye 26 of the viewer who sees the image can see the right stereoscopic image R and the right surrounding image 31, and the left eye 25 sees the left environmental image 30, but sees the right stereoscopic image R. Can't.

3 is a system block diagram of a 3D image display system of the present invention. An embodiment of the present invention includes a display device 41, an image polarization processing device 42, an image filter 43, an image synchronizer 44, and an electronic liquid crystal polarizing glasses 45.

The display device 41 is used for outputting the stereoscopic image 46 and the synchronization signal 47 for screen scanning. The output of the synchronization signal 47 of the screen scanning may be a wired transmission method or a wireless transmission method. The image polarization processing device 42 polarizes the stereoscopic image 46 and then outputs the stereoscopic image 48 having vertical polarization. The image filter 43 receives the stereoscopic image 48 having the vertically polarized light, and appropriately lowers the luminance of the stereoscopic image 48, and then outputs the image 49 having the vertically polarized light and the luminance lowered. The image synchronizing device 44 receives the synchronizing signal 47 for screen scanning and outputs the drive signal 50 of the set of left and right liquid crystal polarizing devices 51 and 52. A pair of left and right liquid crystal polarizers 51 and 52 are mounted on the electronic liquid crystal polarizing glasses 45, and the driving signals of the image 49 and the left and right liquid crystal polarizers 51 and 52 which have vertical polarization and are lowered in luminance. 50), and the polarization action states of the left and right liquid crystal polarizers 51 and 52 are individually set in accordance with this drive signal 50. Accordingly, the image 49 passes through only the left liquid crystal polarizer 51 or the right liquid crystal polarizer 52.

4 (A) and 4 (B) are schematic diagrams showing an optical action on the liquid crystal polarizer of the present invention. The liquid crystal polarizing device is composed of two transparent conductive glasses 60 and 62, a liquid crystal molecular layer 61, and a linear polarizing plate 63 in which the polarization axis is vertical. These two conductive transparent glasses 60 and 62 are used for sealing and protecting the liquid crystal molecular layer 61, and can receive an external electric signal. The liquid crystal polarizer may generate an optical effect of blocking or passing according to the driving signal 50 with respect to the image 49 having vertical polarization and having low luminance. On the other hand, only natural light acts on the passage and no blocking function.

4A is a schematic diagram showing the optical action when the drive signal 50 is at zero potential. At this time, the liquid crystal polarizer is set in a light shielding state, and the image 49 having vertical polarization and having a lower luminance is directly passed through the conductive transparent glass 60 to become an image 64 having vertical polarization. After passing through the liquid crystal molecular layer 61 to which no external voltage is applied, the polarization direction of this image 64 is rotated by 90 degrees, resulting in an image 65 having horizontal polarization. This image 65 passes through the direct conductive transparent glass 62 to form an image 66 having horizontal polarization. The image 66 is inputted to the linear polarizer 63 whose polarization axis is vertical, and is completely removed by the action of the linear polarizer 63 to become the blocking state 67.

Fig. 4B is a schematic diagram showing the optical action when the drive signal 50 is not at zero potential. At this time, the liquid crystal polarizer is set in a pass state, and the image 49 having vertical polarization and lowered in luminance immediately passes through the conductive transparent glass 60 to become an image 64 having vertical polarization. Even after passing through the liquid crystal molecular layer 61 to which an external voltage is applied, the polarization direction of the image 64 is maintained as a vertical direction to become an image 68 having vertical polarization. This image 68 passes directly through the conductive transparent glass 62 to become an image 69 having vertical polarization. This image 69 is input to the linear polarizing plate 63 in which the polarization axis is in the vertical direction, and acts as the linear polarizing plate 63 to pass through to become an image 70 having vertical polarization.

The 3D image display system of the present invention utilizes optical processing of "local visual space shutter processing" and reduces flickering through the screen of the display device, the image polarization processing device, the image filter, the image synchronizing device, and the electronic liquid crystal polarizing glasses. Can be.

Claims (4)

In a three-dimensional (3D) image display system comprising a display device, an image polarization processing device, an image filter, an image synchronizer, and an electronic liquid crystal polarizing glasses, The display device is used for outputting a stereoscopic image and a synchronization signal for screen scanning, and the synchronization signal output for the screen scanning may be a wired transmission method or a wireless transmission method. The image polarization processing apparatus receives a stereoscopic image and polarizes the received stereoscopic image and outputs the polarized image. The photographing filter receives an image and outputs the image after appropriately reducing the luminance of the received image. The image synchronization device receives the synchronization signal of the screen scan, outputs a drive signal of a set of left and right liquid crystal polarizers, A pair of left and right liquid crystal polarizers are mounted on the electronic liquid crystal polarizing glasses, and the image and driving signals of the left and right liquid crystal polarizers are received, and the polarization action states of the left and right liquid crystal polarizers are individually determined according to the driving signals. Set to, The 3D image display system uses a localizing the shuttering process in the limited visual space, the optical action of opening and closing the shutter is limited to the range of the screen of the display device, Effectively reducing flicker when displaying 3D images using display devices such as televisions, monitors, liquid crystal monitors, plasma displays, projectors, etc., as optical effects of shutter opening and closing are not generated for ambient light sources other than the screen. 3D image display system characterized in that. The method of claim 1, The liquid crystal polarizer of the electronic liquid crystal polarizing glasses is composed of two conductive transparent glasses, a liquid crystal molecular layer, and a linear polarizing plate, The two conductive transparent glasses are used to seal and protect the liquid crystal molecular layer, and can receive an external electrical signal, The liquid crystal molecular layer generates an optical action with respect to an image having linear polarization according to an external electric voltage signal, and outputs the image by rotating the polarization direction of the image having linear polarization by 90 degrees when there is no external electric voltage signal. Outputting the image without changing the polarization direction of the image having the linear polarization when there is an external electric voltage signal, The linear polarizer generates an optical action of filtration or passage on an image having the linear polarization. 3D image display device characterized in that. The method of claim 1, The image polarization apparatus is a 3D image display device, characterized in that the linear polarizer. The method of claim 1, And the image filter and the image synchronizer are mounted in a frame of the electronic liquid crystal polarizing glasses.